Dr. Evgenii K

Kurchatov Institute


Dr. Farid Menaa K

Fluorotronics, Inc., USA

Dr.Hicham Elmselem

University of Mohammed Premier,

Dr. Mansoor Zoveidavianpoor

Petronas, Malaysia<br

Dr. Jitang Fan

 Beijing Institute of Technology

Prof. Ravi Kumar Puli

National Institute of Technology

Dr. Murthy Chavali

Chief Scientist NTRC  NEC

Dr. Palani Balaya

National University of Singapore,Singapore

Dr. Xingjian Xue

University of South Carolina

Dr. Mamoun FellahKhenchela

University of Khenchela

Material Science 2019 conference brings together the pioneers doing the most innovative work within the industry and across the globe. Among all International Material science 2019 conferences, in this meeting you will experience unique research outcomes on Material science and Engineering. Material Science and Engineering summit 2019 will bring together International keynote speakers, Industry speakers, panel discussions and more. Speakers are invited from USA, Europe, and Asian industries, to share their unique insights with us. In this summit discussions will be held on Material Science, Engineering, Metallurgy, Polymer science, Nanoscience, Biomaterials and challenges in Material Science.


Conference Name Place Date
Material Science 2019 Singapore June 24-25, 2019

MATSCI 2019 is a place where you can research the systems and theories of Biomaterials, Composites Electronic Materials, Magnetic Materials, Metal Alloys and Metallurgy. This is the honorable gathering for the materials researchers and understudies where you can look at and learn new techniques that are going on the planet. Furthermore, we promise you that, MATSCI 2019 will be the best place to meet the Eminent Researchers of Materials Science, Polymer Science and Engineering. Likewise, Singapore is the best city by populace where you can give your family a magnificent the travel industry experience.
About Singapore:
Singapore is a unique destination to plan a fun-filled holiday with family. Singapore is more than the sum of its numerous attractions. Singapore is both an island and a country, but perhaps its best description is that of city-state. Like the great city-states of the past, it offers civilization and order in the highest degree. Its combination of Western-style development and Eastern-style calm seems to present the best of both hemispheres. Singapore’s progress over the past three decades has been remarkable, yet the island has not been overwhelmed by development.

Material Science and Engineering :
Materials Science and Engineering is an acclaimed scientific discipline, expanding in recent decades to surround polymers, ceramics, glass, composite materials, biomaterials and glasses. Materials science and engineering, involves discovery and design of the new materials. Many of the most pressing scientific problems humans currently face are due to the limitations of the materials that are available and, as a result, major breakthroughs in materials science are likely to affect the future of technology significantly. Materials scientists lay stress on understanding how the history of a material influences its structure, and thus its properties and performance.

Ceramics and Composite Materials:

The primeval ceramics made by humans were pottery objects, including 27,000-year-old figurines, made from clay, either by itself or blended with other materials like silica, hardened, sintered, in fire. Later ceramics were glazed and fired to produce smooth, colored surfaces, decreasing porosity through the use of glassy, amorphous ceramic coatings on top of the crystalline ceramic substrates. Ceramics currently include domestic, industrial and building products, as well as a broad range of ceramic art. In the 20th century, new ceramic materials were developed for use in advanced ceramic engineering, such as in semiconductors. Polymers are investigated in the fields of biophysics and macromolecular science, and polymer science (which encompass polymer chemistry and polymer physics).

Electronic and Magnetic Materials:
The research in Electronic and Magnetic materials field unites the essential values of solid state physics and chemistry for manufacturing of materials science. Intermolecular interactions are also known as molecular interactions. Changes in molecular interactions involves in melting, unfolding, strand separation, boiling. The basic parameters of electronic and magnetic materials are rigid rotation and time dependence. This is related to the computer simulation method to identify the movements physically to interact with atoms and molecules for a given period in order to generate the system for evolution.

Mining, Metallurgy and Materials Science:
Material science has a basic influence on metallurgy also. Powder metallurgy is a term covering a broad assortment of courses in which materials or parts are delivered utilizing metal powders. They can stay away from, or unbelievably diminish, the need to use metal removal shapes and can reduce the costs. Pyro metallurgy consolidates warm treatment of minerals and metallurgical metals and thinks to acknowledge physical and substantial changes in the materials to enable recovery of beneficial metals. An aggregate learning of metallurgy can help us to isolate the metal in a more conceivable way and can be used to a more broad region. The extraction of productive minerals or other topographical materials from the earth is called as Mining and Metallurgy is the field of Materials Science that game plans with physical and manufactured nature of the metallic and intermetallic blends and mixes.

Emerging Smart Materials:
The medieval ages where stone, bronze, steel was used have now led to growth of Ceramics, Minerals from where Metallurgy field aroused. Physics, Chemistry, thermodynamics and several other fields of science have researched metals, alloys, silica and carbon nanomaterial. Material Science has now revolutionized from metals and alloys to semiconductors, plastics, biomaterials, rubbers, polymers, magnetic materials, medicinal implant materials, nanomaterial etc. and it doesn’t stop there yet! Smart structures are devices composed of smart materials capable of sensing stimuli, responding to it and reverting to its original state after the stimuli is removed. Self-Healing Materials, Magnetocaloric and thermoelectric materials, Polycaprolactone are emerging smart structures. Smart structures have the ability to resist natural calamities. Several materials like LiTraCon, Silicene, Aerogels, Graphene, Fullerene, Metamaterials, Quantum Dots and Lithium Ion Batteries have been emerging. These emerging smart materials have found potential applications in health, aerospace, automotive industry etc.

Materials Chemistry and Physics:
Materials Chemistry along with Physics deals with the structure, properties, processing and performance of materials. Applied physics is intended for a particular technological or practical use of materials. Materials characterization is a broad and general process by which a material’s structure and properties are probed and measured. Materials characterization usually done by the major techniques like Microscopy, spectroscopy, macroscopic testing. The scale of the structures observed in materials characterization ranges from angstroms, such as in the imaging of individual atoms and chemical bonds, up to centimeters, such as in the imaging of coarse grain structures in metals.

Manufacturing Innovations:
Manufacturing Innovation is the current trend in production engineering and deals with various manufacturing practices, research, design, development, processes, machines, tools, and equipment. Manufacturing is a process to turn raw materials into an updated or new product in the best economic, efficient and effective way. It involves understanding how products and machinery work/ how to design/ make or use of it. From basic steam engines to high-performance automobiles, air-conditioned environments and jet aircraft, Manufacturing Innovations has changed society for the better.

Nanomaterials and Nanotechnology:
Nanotechnology is the handling of matter on an atomic, molecular, and supramolecular scale. The interesting aspect about nanotechnology is that the properties of many materials alter when the size scale of their dimensions approaches nanometers. Materials scientists and engineers work to understand those property changes and utilize them in the processing and manufacture of materials at the nanoscale level. The field of materials science covers the discovery, characterization, properties, and use of nanoscale materials. Nanomaterials research takes a materials science-based approach to nanotechnology, influencing advances in materials metrology and synthesis which have been developed in support of microfabrication research. Materials with structure at the nanoscale level o have unique optical, electronic, or mechanical properties. Although much of nanotechnology’s potential still remains un-utilized, investment in the field is booming.

Characterization & Testing Of Materials:
Characterization, when used in materials science, refers to the broader and wider process by which a material’s structure and properties are checked and measured. It is a fundamental process in the field of materials science, without which no scientific understanding of engineering materials could be as curtained. Spectroscopy refers to the measurement of radiation intensity as a function of wavelength. Microscopy is the technical field of using microscopes to view objects that cannot be seen with the naked eye. Characterization and testing of material is very important before the usage of materials. Proper testing of material can make the material more flexible and durable. Research indicates the global material testing equipment market generated revenues of $510.8 million in 2011, growing at a marginal rate of 3.1% over the previous year. The market is dominated by the ‘big three’ Tier 1 competitors, namely MTS Systems Corporation, Instron Corporation, and Zwick/Roell, while other participants have performed better regionally, such as Tinus Olsen in North America and Shimadzu Corporation in Asia Pacific.

Biomaterials and Medical Devices:
Biomaterials from healthcare viewpoint can be defined as materials those possess some novel properties that makes them appropriate to come in immediate association with the living tissue without eliciting any adverse immune rejection reactions. Biomaterials are in the service of mankind through ancient times but subsequent evolution has made them more versatile and has increased their usage. Biomaterials have transformed the areas like bioengineering and tissue engineering for the development of strategies to counter life threatening diseases. These concepts and technologies are being used for the treatment of different diseases like cardiac failure, fractures, deep skin injuries, etc. Research is being performed to improve the existing methods and for the innovation of new approaches.

Materials in Industry:
Materials science has a wider range of applications which includes ceramics, composites and polymer materials. Bonding in ceramics and glasses uses both covalent and ionic-covalent types with SiO2 as a basic building block. Ceramics are as soft as clay or as hard as stone and concrete. Usually, they are crystalline in form. Most glasses contain a metal oxide fused with silica. Applications range from structural elements such as steel-reinforced concrete, to the gorilla glass. Polymers are also an important part of materials science. Polymers are the raw materials which are used to make what we commonly call plastics. Specialty plastics are materials with distinctive characteristics, such as ultra-high strength, electrical conductivity, electro-fluorescence, high thermal stability. Plastics are divided not on the basis of their material but on its properties and applications.

Petroleum Chemistry:
Petroleum Chemistry is made of a mixture of different hydrocarbons. The most prolific hydrocarbons found in the chemistry of petroleum are alkanes, these are also sometimes known as branched or linear hydrocarbons. A significant percentage of the remaining chemical compound is the made up of aromatic hydrocarbons and cycloalkanes. Additionally, petroleum chemistry contains several more complex hydrocarbons such as asphaltenes. The primary form of hydrocarbons in the chemistry of petroleum is the alkanes, which are also often named paraffin. These are termed saturated hydrocarbons and the exhibit either branched or straight molecule chains. The paraffin is very pure hydrocarbons and contains only hydrogen and carbon; it is the alkanes which give petroleum chemistry its combustible nature. Depending upon the type of alkanes present in the raw petroleum chemistry it will be suitable for different applications.

Electronics and Photonics:
Electronic materials are the kind of materials which are utilized as core components in various device applications. Changing measurements and level of functionality requires continuous efforts to create best in class materials to meet the innovative difficulties related with advancement of these electronic devices. PC, which has changed the world, is one of the real accomplishments of electronics. Reliability and accuracy are the two key factors in therapeutic diagnostics and medicines, in laboratory practice and industrial operations.
Photonics is the generation and harnessing of light and different types of energy radiant whose quantum unit is the photon. Photonics includes frontier utilization of lasers, optics, fiber-optics, and electro-optical gadgets in various and differing fields of technology like homeland security, aerospace, solid state lighting, healthcare, telecommunication, manufacturing, alternate energy and many others.

Graphene, Fullerenes and 3D Materials:/strong>
One of the recent major trending subject of discussion are the allotropes of carbon like Graphene & Fullerene. Graphene a two dimensional carbon comprised material has shown miraculous properties in terms of strength, light weight and exceptional heating and conducting property, also it is the only allotrope of carbon in which all its reacts from both sides. This compound has raised many eyebrows and it is being researched for various methods of synthesis and for integrating potential its tremendous potential in our day to day life, in devices like semiconductors, biosensors and other 3D materials.
Another form of the carbon allotrope which is undergoing extensive research is fullerene, which is a molecule of carbon in the shape of a ball which has shown many exciting properties among which superconductivity is the most commendable one. It is now widely used for several biomedical applications like photodynamic therapy, drug and gene delivery and also in the design of high-performance X-Ray imaging contrast agents and MRI contrast agents.

Polymer Science and Technology:
Polymers will be the material of the few thousand years and the creation of polymeric parts i.e. green, maintainable, vitality proficient, amazing, low-valued, and so on will guarantee the availability of the finest arrangements around the globe. Manufactured polymers have since quite a while assumed a generally imperative part of display day restorative practice. Numerous gadgets in medication and even some counterfeit organs are developed with progress from engineered polymers and brilliant polymers for microfluidics and Self-mending and reprocessable. Polymer Systems have been utilized in different mechanical applications. Polymer Science can be connected to spare vitality and enhance sustainable power source innovations.

Smart & Hybrid Materials:
Materials which are generally comprised of dissimilar phases which shows significant change in their properties when imposed by an external stimuli for example magnetic or electric field are known as smart materials. In general smart materials are a combination of two or more materials upon which the desired properties are allowed to be expressed. Process control, modeling and simulation aids in fabrication of smart materials. Various smart materials have been fabricated like the smart memory alloys which retain their original shape when heated even after going through a plastic deformation and materials like ferroelectrics and piezoelectrics which produce electric current when imposed by a mechanical stress.
Hybrid Materials are kind of a smart material at a nanometric or molecular. It is generally comprised of two or more constituent one being organic and the other being inorganic. The inorganic part provides the mechanical advantage, whereas the organic part provides the functional advantage. Till date we have got several hybrid materials which aids in corrosion resistance, fire resistance, anti-oxidizing agents etc.

Industrial Engineering:
Industrial engineering has arguably existed as a discipline since the work of Frederick Taylor pioneered scientific management over a century ago. Conversely, the practice of knowledge retention, knowledge sharing and collaboration known as knowledge management has been in existence only within the last three decades.

Electronic Material Development:
Components and materials are the backbone of Electronics and Information Technology (IT) Hardware Sector. Electronic materials are at the core of design, development of electronic component manufacturing, while electronic components are the heart of electronic equipment hardware.

Call for Abstracts

MATSCI 2019 invites abstracts related to the new scientific research in all the fields of recent advances in Material science & engineering and its related aspects. Registrants are invited to submit an abstract for consideration for oral and poster presentation. In general, we encourage more specific to the current research fields representing innovation and recent technologies. Abstracts received will be reviewed by the scientific committee from aspirants and categorized as speaker talks and poster presentations.

Key Discussions on Materialscience 2019

  • Comparison of software for molecular mechanics modeling
  • Materials science in science fiction
  • Timeline of materials technology
  • Surface Engineering and Coatings
  • Analysis and Simulation of Manufacturing Processes
  • Electrical and Electronic Engineering
  • System and Naval Mechatronic Engineering
  • Chemical Engineering Educational Challenges and Development
  • Physical, Theoretical and Computational Chemistry
  • Chemical Engineering Equipment Design and Process Design
  • Materials for Energy Harvesting and Storage
  • Materials for Electronic and Optical Applications
  • Industrial Automation and Process Control
  • Virtual Instrumentation in Automation
  • Controllers and Distributed Control System
  • Inorganic Non-metallic Materials (Glasses, Ceramics, Cement, etc,)
  • Polymeric Materials (Plastics, Rubbers, Fibers, Coatings, etc,)
  • Advanced Composite Materials
  • Engineering materials (metals & alloys, ceramics, polymers, composites)
  • Microstructure-properties relationship